Gene expression, localization, and characterization of endothelin A and B receptors in the human adrenal cortex.

Compelling evidence indicates that the endothelium-derived potent vasoconstrictor endothelin-1 (ET-1) stimulates aldosterone secretion by interacting with specific receptors. Although two different ET-1 receptors have been identified and cloned, the receptor subtype involved in mediating aldosterone secretion is still unknown. Accordingly, we wished to investigate whether the genes of ET-1 and of its receptors A and B are expressed in the normal human adrenal cortex. We designed specific primers for ET-1 and the ETA and ETB receptors genes and developed a reverse transcription polymerase chain reaction (RT-PCR) with chemiluminescent quantitation of the cDNA. In addition, we carried out 125I ET-1 displacement studies with cold ET-1, ET-3 and the specific ETA and ETB ligands BQ123 and sarafotoxin 6C. Localization of each receptor subtype was also investigated by autoradiography. Binding experiments were first individually analyzed by Scatchard and Hofstee plot and then coanalyzed by the nonlinear iterative curve fitting program Ligand. Histologically normal adrenal cortex tissue, obtained from kidney cancer patients (n = 7), and an aldosterone-producing adenoma (APA), which is histogenetically derived from the zona glomerulosa (ZG) cells, were studied. Results showed that the ET-1, ETA and ETB mRNA can be detected by RT-PCR in all adrenal cortices as well as in the APA. The best fitting of the 125I ET-1 displacement binding data was consistently provided by a two-site model both in the normal adrenal cortex (F = 22.1, P < 0.0001) and in the APA (F = 18.4, P < 0.0001). In the former the density (Bmax) of the ETA and ETB subtype was 2.6 +/- 0.5 pmol/mg protein (m +/- SEM) and 1.19 +/- 0.6, respectively. The dissociation constant (Kd) of ET-1, ET-3, S6C, and BQ-123 for each receptor subtype resulted to be within the range reported for human tissue for the ETA and ETB receptors. In the APA tissue the Bmax tended to be lower (1.33 and 0.8 pmol/mg protein, for the ETA and ETB, respectively) but the Kd were similar. Autoradiographic studies confirmed the presence of both receptor subtypes on the ZG as well as on APA cells. Thus, the genes of ET-1 and both its receptor subtypes ETA and ETB are actively transcribed in the human adrenal cortex. Furthermore, both receptor subtypes are translated into proteins in ZG and APA cells.

Hormone receptor expression in human fascial tissue.

Many epidemiologic, clinical, and experimental findings point to sex differences in myofascial pain in view of the fact that adult women tend to have more myofascial problems with respect to men. It is possible that one of the stimuli to sensitization of fascial nociceptors could come from hormonal factors such as estrogen and relaxin, that are involved in extracellular matrix and collagen remodeling and thus contribute to functions of myofascial tissue. Immunohistochemical and molecular investigations (real-time PCR analysis) of relaxin receptor 1 (RXFP1) and estrogen receptor-alpha (ERα) localization were carried out on sample of human fascia collected from 8 volunteers patients during orthopedic surgery (all females, between 42 and 70 yrs, divided into pre- and post-menopausal groups), and in fibroblasts isolated from deep fascia, to examine both protein and RNA expression levels. We can assume that the two sex hormone receptors analyzed are expressed in all the human fascial districts examined and in fascial fibroblasts culture cells, to a lesser degree in the post-menopausal with respect to the pre-menopausal women. Hormone receptor expression was concentrated in the fibroblasts, and RXFP1 was also evident in blood vessels and nerves. Our results are the first demonstrating that the fibroblasts located within different districts of the muscular fasciae express sex hormone receptors and can help to explain the link between hormonal factors and myofascial pain. It is known, in fact, that estrogen and relaxin play a key role in extracellular matrix remodeling by inhibiting fibrosis and inflammatory activities, both important factors affecting fascial stiffness and sensitization of fascial nociceptors.

Expression of the endocannabinoid receptors in human fascial tissue.

Cannabinoid receptors have been localized in the central and peripheral nervous system as well as on cells of the immune system, but recent studies on animal tissue gave evidence for the presence of cannabinoid receptors in different types of tissues. Their presence was supposed also in myofascial tissue, suggesting that the endocannabinoid system may help resolve myofascial trigger points and relieve symptoms of fibromyalgia. However, until now the expression of CB1 (cannabinoid receptor 1) and CB2 (cannabinoid receptor 2) in fasciae has not yet been established. Small samples of fascia were collected from volunteers patients during orthopedic surgery. For each sample were done a cell isolation, immunohistochemical investigation (CB1 and CB2 antibodies) and real time RT-PCR to detect the expression of CB1 and CB2. Both cannabinoid receptors are expressed in human fascia and in human fascial fibroblasts culture cells, although to a lesser extent than the control gene. We can assume that the expression of mRNA and protein of CB1 and CB2 receptors in fascial tissue are concentrated into the fibroblasts. This is the first demonstration that the fibroblasts of the muscular fasciae express CB1 and CB2. The presence of these receptors could help to provide a description of cannabinoid receptors distribution and to better explain the role of fasciae as pain generator and the efficacy of some fascial treatments. Indeed the endocannabinoid receptors of fascial fibroblasts can contribute to modulate the fascial fibrosis and inflammation.

Autocrine-paracrine role of endothelin-1 in the regulation of aldosterone synthase expression and intracellular Ca2+ in human adrenocortical carcinoma NCI-H295 cells.

The role played by endothelin (ET-1) and its receptor subtypes A and B (ET(A) and ET(B)) in the functional regulation of human NCI-H295 adrenocortical carcinoma cells has been investigated. Reverse transcription-PCR with primers specific for prepro-ET-1, human ET-1 converting enzyme-1, ET(A), and ET(B) complementary DNAs consistently demonstrated the expression of all genes in NCI-H295 cells. The presence of mature ET-1 and both its receptor subtypes was confirmed by immunocytochemistry and autoradiography, respectively. Aldosterone synthase (AS) messenger RNA was also detected in NCI-H295 cells, and AS gene expression was enhanced by both ET-1 and the specific ET(B) agonist IRL-1620; this effect was not inhibited by either the ET(A) antagonist BQ-123 or the ET(B) antagonist BQ-788. A clear-cut increase in the intracellular Ca2+ concentration in NCI-H295 cells in response to ET(B), but not ET(A), activation was observed. In light of these findings, the following conclusions can be drawn: 1) NCI-H295 cells possess an active ET-1 biosynthetic pathway and are provided with ET(A) and ET(B) receptors; 2) ET-1 regulates in an autocrine/paracrine fashion the secretion of aldosterone by NCI-H295 cells by enhancing both AS transcription and raising the intracellular Ca2+ concentration; and 3) the former effect of ET-1 probably involves the activation of both receptor subtypes, whereas calcium response is exclusively mediated by the ET(B) receptor.

Endothelin-1 and its receptors A and B in human aldosterone-producing adenomas.

Endothelin-1 stimulates aldosterone secretion by interacting with specific receptors. Accordingly, we wished to investigate endothelin-1, endothelin-A (ETA) receptor, and endothelin-B (ETB) receptor gene expression, localization, and properties in aldosterone-producing adenomas and in the normal human adrenal cortex. We carried out 125I-endothelin-1 displacement studies with cold endothelin-1, endothelin-3, the specific ETA antagonist BQ-123, and the specific ETB weak agonist sarafotoxin 6 C and coanalyzed data with the nonlinear iterative curve-fitting program LIGAND. We also studied gene expression with reverse transcription-polymerase chain reaction with specific primers for endothelin-1, ETA, and ETB complementary DNA. Normal adrenal cortices from consenting kidney cancer patients (n = 2) and aldosterone-producing adenomas (n = 4) were studied; for the latter, surrounding normal cortex and kidney biopsy tissue served as controls. To further localize the receptor subtypes, tissue sections were studied by autoradiography in the presence and absence of 500 nmol/L BQ-123, 100 nmol/L sarafotoxin 6 C, and 1 mumol/L cold endothelin-1. In all tissues examined, endothelin-1, ETA, and ETB messenger RNAs were easily detected. However, in aldosterone-producing adenomas, both receptors' genes were expressed at a higher level than in the kidney.(ABSTRACT TRUNCATED AT 250 WORDS)

Endothelin adrenocortical secretagogue effect is mediated by the B receptor in rats.

We investigated the gene expression and localization of endothelin-1 (ET-1) receptor subtypes ET(A) and ET(B) in the rat adrenal cortex as well as their involvement in the corticosteroid secretagogue effect of ET-1 in vitro. Reverse transcription-polymerase chain reaction with primers specific for ET(A) and ET(B) cDNAs demonstrated the expression of both receptor genes in homogenates of adrenocortical tissue. However, in isolated zona glomerulosa and zona fasciculata cells, only ET(B) mRNA was detected. Autoradiographic examination of the selective displacement of 125I-ET-1 binding by BQ-123 and BQ-788 (specific ligands for ET(A) and ET(B), respectively) indicated that zona glomerulosa possesses both ET(A) and ET(B), whereas zona fasciculata is exclusively provided with ET(B). ET-1 enhanced in a concentration-dependent manner aldosterone and corticosterone secretions of dispersed zona glomerulosa and zona fasciculata cells, respectively. The ET(B) antagonist BQ-788 markedly reduced the secretory response of zona glomerulosa cells and completely suppressed that of zona fasciculata cells, whereas the ET(A) antagonist BQ-123 was ineffective. These findings indicate that in the rat, the adrenocortical secretagogue action of ET-1 is mediated by the ET(B) receptor subtype and that the ET(A) receptor is not directly involved in such an effect.

Endothelin-1 stimulates steroid secretion of human adrenocortical cells ex vivo via both ETA and ETB receptor subtypes.

The role played by endothelins (ETs) and their receptor subtypes (ETA and ETB) in the regulation of steroid hormone secretion in human adrenal gland remains unclear. Therefore, we investigated the gene expression of ET-1 and its receptors in highly pure preparations of human adrenocortical cells and the effect of ET-1 on their secretory activity. Reverse transcription-PCR with primers specific for prepro-ET-1, ET-converting enzyme-1, ETA, and ETB complementary DNAs demonstrated the expression of all of these genes in human adrenocortical cells. ET-1 increased the secretion of aldosterone and cortisol by enhancing both earlier and late steps of their synthesis. The secretory response to ET-1 was partially (60%) inhibited by BQ-123 and BQ-788, which are selective antagonists of the ETA and ETB receptors, respectively. When added together, the two antagonists suppressed the secretagogue effect of ET-1. Collectively, these findings suggest that ET-1, acting via both ETA and ETB receptors, may exert an autocrine/paracrine regulation of the function of the human adrenal cortex.

Endothelin-1[1-31]: a novel autocrine-paracrine regulator of human adrenal cortex secretion and growth.

Endothelin (ET)-1[1-21] stimulates steroid secretion and zona glomerulosa growth and is expressed in the human and rat adrenal cortex together with its receptor subtypes A and B (ETA and ETB). Although ET-1[1-21] is generated from bigET-1 by an ET-converting enzyme (ECE-1), there is evidence of an alternative chymase-mediated biosynthetic pathway leading to the production of an ET-1[1-31] peptide, the role of which in adrenal pathophysiology is largely unknown. Gene expression and immunohistochemical studies allowed localization of chymase in the normal human adrenal cortex. Sizable amounts, not only of ET-1[1-21] but also of ET-1[1-31], were found in the adrenal vein plasma of three patients. ET-1[1-21] and ET-1[1-31] elicited a clear-cut secretory response by dispersed human adrenocortical cells, ET-1[1-31] being significantly less potent than ET-1[1-21]. The secretagogue effect of ET-1[1-31] was abolished by the ETA receptor antagonist BQ-123 and was unaffected by the ETB receptor antagonist BQ-788. Because, in humans, the secretagogue effect of ET-1[1-21] involves both ETA and ETB receptors, the weaker action of ET-1[1-31] could be attributable to a selective ETA receptor activation. Two lines of evidence support this contention: 1) ET-1[1-31] was more effective than ET-1[1-21] in stimulating ETA-mediated cell proliferation of human adrenocortical cells cultured in vitro; and 2) autoradiography showed that a) ET-1[1-31] displaced in vitro [(125)I]ET-1[1-21] binding to the ETA, but not ETB receptors, in human internal thoracic artery rings; and b) BQ-123, but not BQ-788, eliminated [(125)I]ET-1[1-31] binding in the rat adrenal cortex.

Proadrenomedullin-derived peptides as autocrine-paracrine regulators of cell growth.

Proadrenomedullin (pADM)-derived peptides, adrenomedullin (ADM) and pADM N-terminal 20 peptide (PAMP), are hypotensive peptides, which are expressed, along with their receptors, in several tissues and organs, the function of which they regulate by acting in an autocrine-paracrine manner. Apart from their involvement in the regulation of blood pressure and fluid and electrolyte homeostasis, pADM-derived peptides appear to play a role in the modulation of cell and tissue growth. Evidence has been provided that ADM: 1) favors the remodeling of cardiovascular system under pathological conditions, by exerting an antiapoptotic effect on endothelial cells and an antiproliferogenic and antimigratory action on vascular smooth-muscle cells during neointimal hyperplasia, and by decreasing proliferation and protein synthesis of cardiac myocytes and fibroblasts. These last two effects are mediated by calcitonin gene-related peptide type 1 (CGRP1) receptors coupled to the adenylate cyclase (AC)/protein kinase (PK) A-dependent cascade; 2) inhibits proliferation and enhances apoptosis of kidney mesangial cells, through the modulation of mitogen-activated PK (MAPK) cascades; 3) stimulates proliferation of adrenal zona glomerulosa cells, acting via CGRP1 receptor coupled to the tyrosine kinase-dependent MAPK cascade, thereby possibly being involved in the maintenance and stimulation of adrenal growth; 4) enhances proliferation of skin and mucosa epithelial cells and fibroblasts, by activating CGRP1 receptor coupled to the AC/PKA signaling pathway; and 5) enhances proliferation of several tumor-cell lines through the activation of the AC/PKA cascade, which suggests a potential role for ADM as promoter of neoplastic growth. The growth effects of PAMP have been far less investigated: findings indicate that this peptide, like ADM, enhances adrenal zona glomerulosa-cell proliferation, and, in contrast with ADM, depresses DNA synthesis in some cancer-cell lines. Both pADM-derived peptides are thought to be involved in embryogenesis, such a contention being based on the demonstration of high pADM-gene expression during the crucial phases of organ growth and differentiation.

Evidence for a paracrine role of adrenomedullin in the physiological resetting of aldosterone secretion by rat adrenal zona glomerulosa.

Adrenomedullin (ADM) has been recently found to directly inhibit agonist-stimulated aldosterone secretion by dispersed zona glomerulosa (ZG) cells and to stimulate basal catecholamine release by adrenomedullary fragments. In light of the fact that catecholamines enhance aldosterone secretion acting in a paracrine manner, we have investigated whether these two effects of ADM may interact when the integrity of the adrenal gland is preserved. ADM increased basal aldosterone output by adrenal slices containing a core of adrenal medulla, and the effect was blocked by the beta-adrenoceptor antagonist l-alprenolol. In contrast, ADM evoked a moderate inhibition of K(+)-stimulated aldosterone production, and the blockade was complete in the presence of l-alprenolol. The in vivo bolus injection of ADM did not affect plasma aldosterone concentration (PAC) in rats under basal conditions. Conversely, when rat ZG secretory function was enhanced (by sodium restriction or infusion with angiotensin-II [ANG-II]) or depressed (by sodium loading or infusion with the angiotensin-converting enzyme inhibitor captopril), ADM evoked a sizeable decrease or increase in PAC, respectively. The prolonged infusion with the ADM receptor antagonist ADM(22-52) caused a further enhancement of PAC in sodium-restricted or ANG-II-treated rats, and a further moderate decrease of it in sodium-loaded or captopril-administered animals. RIA showed that ADM plasma concentration did not exceed a concentration of 10(-11) M in any group of animals. Under basal conditions, ADM adrenal content was 1.2-2.0 pmol/g, which may give rise to local concentrations higher than 10(-8) M (i.e. well above the minimal effective ones in vitro). ADM adrenal concentration was markedly increased (from two-fold to three-fold) by both ZG stimulatory and suppressive treatments. Collectively, our findings suggest that in vivo 1) ADM, in addition to directly inhibit aldosterone secretion, may enhance it indirectly by eliciting catecholamine release, the two actions annulling each other under basal conditions; 2) under conditions leading to enhanced aldosterone secretion, the direct inhibitory effect of ADM prevails over the indirect stimulatory one, and the reverse occurs when aldosterone secretion is decreased; and 3) the modulatory action of ADM on the aldosterone secretion has a physiological relevance, endogenous ADM being locally synthesized in adrenals.

Human pheochromocytomas, but not adrenal medulla, express glucagon-receptor gene and possess an in vitro secretory response to glucagon.

Glucagon-receptor mRNA was detected by reverse transcription-polymerase chain reaction in three human pheochromocytomas, but not in four normal adrenal medullas. Quantitative autoradiography demonstrated the presence of abundant [(125)I-Thyr(10)]glucagon binding sites in pheochromocytomas, which were displaced by both cold glucagon and the glucagon receptor antagonist Des-His(1)[Glu(9)]glucagon amide (GR-A). Adrenal medulla was weakly labeled, and the binding was not displaced by GR-A. Glucagon enhanced epinephrine and norepinephrine release by pheochromocytoma slices, minimal and maximal effective concentrations being 10(-8) M and 10(-6) M. Adrenomedullary slices evidenced a weak catecholamine response only to 10(-5) M glucagon. GR-A abolished the secretory response to glucagon of pheochromocytomas, but not of adrenal medullas. Collectively, these findings indicate that human pheochromocytomas, but not adrenal medulla, express glucagon receptors and possess a marked secretory response to glucagon, thereby providing the rationale to explain the specificity of the glucagon provocative test in the diagnosis of pheochromocytoma.

Distribution, functional role, and signaling mechanism of adrenomedullin receptors in the rat adrenal gland.

Adrenomedullin (ADM) is a hypotensive peptide, highly expressed in the mammalian adrenal medulla, which belongs to a peptide superfamily including calcitonin gene-related peptide (CGRP) and amylin. Quantitative autoradiography demonstrated the presence of abundant [125I]ADM binding sites in both zona glomerulosa (ZG) and adrenal medulla. ADM binding was selectively displaced by ADM(22-52), a putative ADM-receptor antagonist, and CGRP(8-37), a ligand that preferentially antagonizes the CGRP1-receptor subtype. ADM concentration-dependently inhibited K+-induced aldosterone secretion of dispersed rat ZG cells, without affecting basal hormone production. Both ADM(22-52) and CGRP(8-37) reversed the ADM effect in a concentration-dependent manner. ADM counteracted the aldosterone secretagogue action of the voltage-gated Ca2+-channel activator BAYK-8644, and blocked K+- and BAYK-8644-evoked rise in the intracellular Ca2+ concentration of dispersed ZG cells. ADM concentration-dependently raised basal catecholamine (epinephrine and norepinephrine) release by rat adrenomedullary fragments, and again the response was blocked by both ADM(22-52) and CGRP(8-37). ADM increased cyclic-AMP release by adrenal-medulla fragments, but not capsule-ZG preparations, and the catecholamine response to ADM was abolished by the PKA inhibitor H-89. Collectively, the present findings allow us to draw the following conclusions: (1) ADM modulates rat adrenal secretion, acting through ADM(22-52)-sensitive CGRP1 receptors, which are coupled with different signaling mechanisms in the cortex and medulla; (2) ADM selectively inhibits agonist-stimulated aldosterone secretion, through a mechanism probably involving the blockade of the Ca2+ channel-mediated Ca2+ influx; (3) ADM raises catecholamine secretion, through the activation of the adenylate cyclase/PKA signaling pathway.

Cerebellin stimulates the secretory activity of the rat adrenal gland: in vitro and in vivo studies.

Cerebellin is a 16-aminoacid peptide widely distributed in the central nervous system, where it exerts neuromodulatory functions. Cerebellin is contained in human adrenal medulla, and it has been recently demonstrated that cerebellin elicits catecholamine release by human adrenal in vitro. Aim of the present study was to ascertain whether cerebellin affects adrenal function in the rat. Cerebellin concentration-dependently (from 10(-9)to 10(-7)M) increased norepinephrine (but not epinephrine) and cyclic-AMP production by adrenomedullary tissue in vitro. The norepinephrine response to 10(-7)M cerebellin was blocked by the protein kinase (PK) A inhibitor H-89, but not by the phospholipase C inhibitor U-73122 or the PKC inhibitor calphostin-C. Cerebellin did not affect aldosterone and corticosterone secretion of dispersed zona glomerulosa and zona fasciculata-reticularis adrenocortical cells. Cerebellin concentration-dependently (from 10(-8)to 10(-7)M) enhanced norepinephrine release by in situ perfused rat adrenals. Cerebellin (10(-7)M) also elicited a significant rise in aldosterone and corticosterone output, and this effect was annulled by either the beta1-adrenoceptor antagonist l -alprenolol or H-89. Collectively, the present findings allow us to conclude that cerebellin 1) directly stimulates norepinephrine release via the adenylate cyclase/PKA-dependent signaling pathway; and 2) indirectly enhances adrenocortical secretion in vivo, through a paracrine mechanism involving medullary catecholamine release.

Adrenomedullin (ADM), acting through ADM(22-52)-sensitive receptors, is involved in the endotoxin-induced hypotension in rats.

The possible involvement of adrenomedullin (ADM) in the endotoxin-induced hypotension has been investigated in the rat. Lipopolysaccharide (LPS, 500 micrograms/kg intraperitoneum) caused a severe decrease in the blood pressure (BP), reaching maximum 2-3 h after the injection and subsiding after 12 h. The putative ADM-receptor antagonist ADM(22-52) (3 nmol/kg) counteracted LPS-induced BP lowering at 1 and 2 h, and reversed it at 3 and 6 h. CGRP(8-37), a selective antagonist of the CGRP1 receptors, was ineffective. Both ADM(22-52) and CGRP(8-37) did not evoke significant changes in the basal BP. Our findings provide strong support to the view ADM overproduction plays a major role in the LPS-induced decrease in BP, and suggest a potentially important therapeutic effect of the blockade of ADM(22-52)-sensitive receptors during endotoxic shock.

Expression of adrenomedullin and its receptors in the human adrenal cortex and aldosteronomas.

Adrenomedullin (ADM) is a hypotensive peptide, that derives from the proteolytic cleavage of pro(p)ADM and acts through at least two subtypes of receptors, called L1-receptor (L1-R) and calcitonin receptor-like receptor (CRLR). CRLR may function as a calcitonin gene-related peptide (CGRP) or a selective ADM receptor depending on the expression of the subtype 1 or the subtypes 2 and 3 of a family of proteins, referred to as receptor-activity-modifying proteins (RAMPs). Although adrenal cortex is known to be one of the main target organs of ADM, its expression of the ADM and its receptor has not yet been extensively investigated. Reverse transcription (RT)-polymerase chain reaction (PCR) revealed the expression of the pADM and peptidyl-glycine alpha-amidating monooxigenase (PAM) genes in four human adrenal cortexes and four aldosteronomas. Since PAM is the enzyme that converts immature ADM to the mature and active form, these findings suggest that the two tissues are able to produce ADM. RT-PCR also demonstrated high levels of L1-R mRNA and relatively low levels of CRLR mRNA, as well as the presence of specific mRNAs for the three RAMPs, thereby indicating that human adrenal cortex and aldosteronomas are provided with the two subtypes of classic ADM receptors. In conclusion, our investigation provides the first evidence that human adrenal cortex and aldosteronomas express the ADM system, that may play a role in the paracrine or autocrine control of their functions.

Expression and function of adrenomedullin and its receptors in Conn's adenoma cells.

Adrenomedullin (ADM) is a hypotensive peptide, that derives from the proteolytic cleavage of pro(p)ADM and acts through two subtypes of receptors, called L1-receptor (L1-R) and calcitonin receptor-like receptor (CRLR). CRLR may function as a calcitonin gene-related peptide or a selective ADM receptor depending on the expression of the subtype 1 or the subtypes 2 and 3 of a family of proteins, named receptor-activity modifying proteins (RAMPs). Reverse transcription (RT)-polymerase chain reaction (PCR) allowed the detection of pADM mRNA in dispersed cells of eight Conn's adenomas (aldosteronomas). These cells also expressed peptidyl-glycine alpha-amidating monooxigenase, the enzyme converting immature ADM to the mature form, and contained sizeable amounts of ADM-immunoreactivity as measured by radioimmunoassay. RT-PCR also demonstrated the presence in aldosteronoma cells of the specific mRNAs of L1-R, CRLR and RAMPs 1-3. ADM (10(-8) M) inhibited angiotensin-II (10(-9) M)-simulated aldosterone secretion from cultured aldosteronoma cells, without affecting basal production. ADM (10(-8) M) also enhanced basal proliferation rate of cultured cells, as estimated by the 5-bromo-2'-deoxyuridine immunocytochemical technique. Both effects of ADM were annulled by the ADM-receptor selective antagonist ADM22-52 (10(-7) M). In conclusion, our study provides evidence that aldosteronoma cells express both ADM and ADM22-52-sensitive receptors. These findings, coupled with the demonstration that ADM exerts an aldosterone antisecretagogue action and a proliferogenic effect on cultured aldosteronoma cells, make it likely that endogenous ADM system plays a potentially important role in the paracrine or autocrine functional control of Conn's adenomas.

An easy-to-handle microfluidic device suitable for immunohistochemical procedures in mammalian cells grown under flow conditions.

Microfluidic, the technology that manipulates small amount of fluids in microscale complex devices, has undergone a remarkable development during the last decade, by targeting a significant range of applications, including biological tests and single-cell analysis, and by displaying many advantages such as reduced reagent consumption, decreased costs and faster analysis. Furthermore, the introduction of microfluidic tools has revolutionized the study of vascular functions, because the controlled three-dimensional environment and the continuous perfusion provided by the microdevice allow simulating the physiological characteristics of the circulatory system. Researchers interested in the study of vascular physiology, however, are often hampered by the difficulty in handling reduced number of cells after growth in these devices. This work shows how to apply different protocols commonly used in biology, such as the immunofluorescence technique, to cells grown in reversibly-bound microfluidic devices, obtaining results comparable to those retrieved under static conditions in multiwells. In this way, we are able to combine the advantages of microfluidic, i.e., application of continuous flow and shear stress, with classical protocols for the study of endothelial cells.